Machine for manufacturing incandescent lamps



Nov. 2, 1937. i J. F. DONOVAN ET AL MACHINE FOR MANUFACTURING INCANDESCENT LAMPS Filed June 30, 1934 7 Sheets-Sheet l Then- Attorney;-

7 Inventors I John F? Donovan;

George Illin worth,

i 8 an o a a 4 -2,1937. J. F. DONQVAN Em 2,098,03

MACHINE FOR MANUFACTURING INCANDESCENT LAMPS Filed June so. 1934 7 Sheets-Sheet 2 I l are 852 1 1 g 572 B77 B76 Inver'wtors: John F. Donovan, George Illingworth,

Their Attorne y.

N v. 2', 1931* J. F. DONOVAN ET AL 2,098,030

MACHINE FOR MANUFACTURING INCANDESCENT'LAMPS Filed June so, 1954 7 Sheets-Sheet 3 Inventors: John F? Donovan, George lllingwortm Nov. 2, 1937. J. F. DONOVAN E-T AL- I 2,093,030

MACHINE FOR MANUFACTURING INCANDESCENT LAMPS Inventor-s: John F. Donovan, George I Hin worth,

Then Atborne g- Nov. 2, 193 7.

J. F. DONOVAN ET A| 2,098,030

MACHINE FOR MANUFACTURING INCANDESCENT LAMPS 7 Sheets-Sheet 5 Filed Jun so, 1934 Inventors: John F. Donovan, Georgellli'n worth,

TheiT Attorng.

Nov. 2, 1937- J. F. DONOVAN ET AL V MACHINE FOR MANUFACTURING INCANDESCENT LAMPS Filed June 30, 1934 "7 Sheets-Sheet 6 Inventors: John 7-. Donovan. George II I in gworth,

by Their Attorney- NW 2, mm.

J. F. DONOVAN ET AL 2,098,030 MACHINE FOR MANUFACTURING INCANDESCENT LAMPS v Filed June '50, 1954 7 Sheets-Sheet 7 John F Donovan, 1 George Illingworth, 1.4.: 5

V T ei h Attdrnqg.

Patented Nov. 2, 19 37 V v i.

UNITED gTATES PATENT OFFICE MACHINE FOR MANUFACTURING INCAN- DESCEN'I' LAIVIPS John F. Donovan and George lllingworth, East Gleveland, hio, assignors to General Electric Cgmpanma corporation of New York s pue non June so, 1934, Serial No. 723,151 :16 Claims. (01. 176-3) Our invention relates to the manufacture of stationary mount chute, mount escapement and electric lamps and more particularly to mamount transfer mechanism; Fig. 14 is a plan view .chines for manufacturing miniature-lamps of of the mount chute indexing mechanism;Fig.15is the type comprising a mount consisting of two a diagrammatic perspective view of the cam shafts juxtaposedlead wires held together by an insuand associated operating mechanism; Fig. 16 is 5 latins y d supp rt n a s t fi t to a section through the storage chute indexing which these leads supply current. Because ofcontrol clutch; Fig. 17 is a wiring diagram of the their small size, the manufacture of parts for indexing control mechanism and of the bulb feed such lamps has been particularly difficult. Variarresting mechanism; Figs. 18 and 19 are front ous operations have been performed manually and .top views of'the mount escapement jaws; 10 because m hin f r in these perations Figs. 20 and 21 are top and bottom views of the have not existed and this has added to the diflibulb escapement mechanism; Figs. 22 and 23 are y- 0f t s 'ep s the eedi side and top views partially in section of the of the miniature lamp mountsinto a sealing ma-' bulb turret; Fig. 24 is a plan view of the bulb chine a d another op rati n is th p acing aiid transfer arresting mechanism; Figs. 25 and 26 15 positioning of the mount in the bulb. Still anare top and side views of the sealing machine other operation is'the' transfer of thebulb a'sunloading mechanism; Fig. 2'? is a perspective sembly from the sealing machine to the exhaustview of a portion of the lamp conveyor chain and ing machine and its insertion into said machine. Fig. 28 is a plan view of the exhaust machine The principal object of our invention is to loading mechanism.

. pr v de a s n le m ch ne o ma c u ng The series of operations of the machine comminiature lamp mounts, for sealing said mounts prising our invention as shown in Fig. 1, begins in a bulb, and for exhausting and tipping ofi with the mount manufacturing machine A which Said lamps, combined With pp p t t n f r manufactures lamp mounts of the type shown in and feed mechanisms. A -feature of our inven- Fig. 2. The machine is.of the type disclosed in 9,5 i n i th t r m ns wh h re iv s h 11.5. Patent 1,733,881 issued October 29, 1929 to mounts from the ma in which y are Illingworth, which is a'turret type machine havmade and the mechanism by which they are autoing heads at the positions indicated, h t mati lly fed to' the sealing machine. Another ret turns in a counterclockwise direction'and the a 30 object of our invention is to provide mechanism mount is completely manufactured as it enters 30 for placing the mount so that after sealing the position R. e mount is taken from this posifilamentis properly located in the bulb. Other tion by the t ret unloading mechanism B and Mobiects and features of the m chine f 11 ntransferred to position S. During the transfer Ventien Will app the detailed es p -'an electric current is passed through the leadof specieswhich follows and from the accoming-in wires and filament and, should insufilcient 35 panying drawings. a energy pass, the unloading mechanism will stop In h d wi s 1 i a p n view of he at an intermediate oint and discard the mount., machine of our invention; Fig. 2 is aside ele- The chute loading mechanism C takes the vation of a mount produced by our machine; mounts at position S from the turret unloading 40 Figs. 3 and 4 are side and end views of the mount mechanism and transfers them to the storage 40 machine unloading mechanism; Figs. 5 and 6 chute D which is located oppofite position S. are side and end views of the operating mecha- There are in this instance eight of the chutes D nism therefor and associated mount counting whichpivot about a centrally located point and mechanism; Fig. '7 is the wiring diagram of the tilt down in the direction -of said point. The mount testing circuit of the unloading mechamounts placed thereon slide down toward the 45,

msm; Fig. 8 is a sideyiew of the storage chute inner end and are counted by a mechanism oploading;Fig.Qisasldevievrofthe eratingwiththetnrretmechanim jawsthereo'fatnghtanglestotheformerandon After adeflnite number of mounts havebeen anenlargedscalafiglflisasideelevationof p1acedonthechute"itswingsl80tothe1mthemountstoragechutoszfigllisanendview ioadingpositionoragainstotherchntesaheadotio lzisg fideelevafimoffllestafimmflmt vancedintosaidposiiion. 'niestatlonarychnte chute, mount acapemmt mechanism, Eislocatedattheunloadimpositlonandthe transiernwnntturretbulbteed andstora'ge chute is tilted in the opposite direction transfer echanism; Fig.13iaaplauvie'oithfl ther atscthe mounts slide down onto thesta-Ji tionary chute. Storage for a number of mounts is furnished by the chute and means are provided for releasing the storage chute so that another may take its place when the number of mounts thereon is considerably reduced.- The mounts are released to the end T ofthe chute by a mount escapement mechanism F (not shown in Fig. 1) which releases them one at a time.

From the lower end T of the stationary chute the mounts are taken by the mount transferv mechanism G to jaws of the mount turret H at position U. The escapement mechanism operates in conjunction with the beads of the mounts which lie in one plane and are not entangled. The mount turret indexes intermittently and carries the jaws into the unloading position v. Here it is placed in a bulb fed into the machine through the bulb escapement mechanism J and bulb turret K. The bulbs are fed into the turret by the escapement mechanism and are transferred to position V by rotation of the turret. The bulb transfer mechanism L then grips the bulb and lifts it to a position adjacent a jaw in the turret \H which releases said mount whereupon the bulb is transferred by'mechanism L to a head W in the sealing machine M.

The sealing machine M is of the type disclosed in Patent 1,742,153 issued December 31, 1929 to Stiles et a1. and butt seals a tube to the bulb with the lead wires of the mount sealed in the joint thus formed. The machine turns in a counter clockwise direction and all operations are completed as the bulb assembly indexes into position X. The bulb assembly is unloaded here by the transfer mechanism N which places said assembly on the conveyor chain 0. Intermittent indexing of the chain carries the assembly into position Y from which-it is taken by the transfer mechanism P and placed in the head of an exhaust machine Q at position Z. The exhaust machine correspondsto that portion of the machine shown in Patentf1.736,766 issued November 19, 1929 to Burrows for exhausting, although the machine heads are inverted. The products from this machineareglass enclosures having a filament therein, either exhausted or gas-filled and having leading-in wires extending therefrom.

In detail, the machine of our invention consists of the mount making machine A indicated in Fig. 1, preferably of the type shown in the U. S. Patent 1,733,881 hereinbefore referred to, which manufactures miniature lamp mounts of the type shown in Fig. 2. Such mounts preferably comprise a pair of leading-in wires 30 and 3|,

juxtaposed portions of which are held together by a bead 32 of insulating material such asglass and which support a filament 33 at their inner vends. The outer ends of the leading-in wires extend transversely to the inner ends and are each I preferably bent back so as to be at an angle of 3 approximately 70 to the midportion and extend ing in opposite directions therefrom. The mount is complete as said machine indexes thehead in -'which it rests into position R, the midportions of the leading-in wires being disposed vertically on either side of the jaw, 34 (Fig. 3) and clamped thereto by jaws 35 and 36, the filament 33 being uppermost.

The mount is taken from the turret jaws by the unloading mechanism B shown in Figs. 3 and 4. The mechanism comprises a pair of fixed jaws BI and B2 mounted separately on arm B3 and insulated therefrom by the sheet B4 of insulation and by insulating bushings (not shown) about screws B5.

' between s'crews B23 of arm B3, causes arm B3 B29 pivots about pin B33.

, armature B44 which is attached to a midpoint As the; mount makin outer jaws 35 and 36 of the machine turret have been released. The unloading jaws are closed by a clockwise turning of shaft B9 which rides in standard Bill and supports arm B3. The first turning of shaft B9 results in roller BH of lever B|2 falling to a low part of cam Bl3 on said shaft and causes lever Bl2 to actuate the jaws through yoke Bl4. Connection to jaw B6 is made through an insulating bushing on screw BIS and to jaw B! through arm Bl 6 and a similar bushing and screw Bl I. The arm BIB is attached 3 to the yoke Bl4 by-screws Bill which lie in slots in said armand is kept forward as far as possible by a spring BIB which causes both the jaws to bear equally against the. mount. The jaws are closed by spring B20 which extends between lever Bl2'and apost in arm. B3 and keeps roller Bll against cam Bl3. Havinggripped the mount the jaws swing into the position shown .in Fig. 4 as the friction produced by bearing cap B2l, which is located below leaf spring B22 extending to move with the rotating shaft B9. On reaching the. position shown in Fig. ,4 further rotation of the arm is prevented by it striking stop screw B24 in the standard, whereupon the high part of cam Bl3 is carried below roller BH and the jaws are opened. A similar stop screw B25 is located at the other positionof the arm. Rotation of shaft B9 results from vertical movement of rod B26 which operates through arm'BZI and is operated as shown in Fig. 5 by cam B28 through lever B29.- The cam is located on a cam shaft of the mount making machine below the table B30 on which theistandard BIO is mounted and operates lever B29 through engagement of roller B3| thereof riding in its ways B32. Lever In connection with the unloading mechanism means are provided for testing the mount by passing a current therethrough. As shown diagrammatically in Fig. 7 and in Figs. 3 and 4, electrical energy from a'battery B34 is connected so as to pass' from one movable jaw, through the leading-in wire in contact therewith, the filament and through the opposite leading-in wire to the other movable jaw. A relay B35 also located in this circuit causes a circuit of greater voltage throughsolenoid B36 to be closed if suificient current can be passed through the mount. The current inthe coilB31 of the relay causes the armature B38'to be pulled into contact with contact B39 against the pull of spring B40. The solenoid B36 as shown in Fig. 6 is mounted'on bracket B4I' extending from the frame of the machine (not shown) and operates lever B42 which pivots about screw B43, by means of the thereof. Movement of lever B42 operates rod B45 which turns lever B46 causing movement of rod B41. Lever B46 turns about pin B48 in a bracket B49 extending from the bottom of the table and operates against the pull of spring B50 which extends between a post in the table and one in said lever. As shown in Fig. 3 rod B41 is attached 'to lever B5! which pivots about screw B52 in the standard and during operation. of the solenoid B36 pulls stop rod B53 in, out of the path OI movement of arm B3. Should no current be nocurrent willpass through the solenoid and the arm B3 will be arrested by stop rod B53 resulting in the dumping of the mount at this position. The defective mounts not taken by the unloading mechanism are blown from the turret by air from pipe B53.

Too many mounts must not be placed on each I storage chute and therefore the good mounts carried by the unloading mechanism are counted or recorded. This mechanism is shown in Figs. 5 and 6 and consists of a ratchet wheel'Bil which operated as rod B26 moves upward since screw arm B51 upward. During the movement pawl B58 on pin B59 in arm B51'advances the ratchet wheel B54 one notch providing the mount being transferred is acceptable, but if the mount is defective, the cam B59 stays in position and holds the pawl away from the wheel. This action reas roller Bil of arm B62 thenrides on cam B60 and, since both arm B62 and the pawl are pawl against the ratchet wheel. Arm B51 is slidably mounted on shaft B64 and is returned to its former position by spring B65 which extends between a post in said arm and a post in a bracket B56 attached fixedly to shaft B64. Shaft B54 is fixedly mounted in support bracket B61 and carties arm BB8 which is. made to move with the ratchet wheel due to the bolt BS9 therebetween. With the completion of a revolution of the ratchet wheel, block B10 is carried below cam B1 I in lever B12, turning the lever and thereby pulling stop slide B13 down permitting another chute 'to be indexed into position as later explained.

Immediate return of lever B12 to the up position is produced by spring B14 which extends between a post in the table and said lever. The lever B12 turns about a pin B15 in'bracket B61 and is connected to slide B13 which rides in ways in bracket B11 by stud B16. Arm B68 does not move free about shaft Bil but carries a friction producing pad B18 which is backed up witha spring B19 and screw B80 so the'weight of said arm does 'not pull the ratchet wheel around.

The mounts are taken from the unloading mechanismby the storage chute loading mechanism C shown in Figs. 8 and 9. This mechanism consists of two jaws CI and C2 which grip themount as shown. The jaw CI is mounted on shaft C3 and the jaw C2 is mounted through screw Cl on sleeve C5. Shaft C3 is mounted in passes vertically through standard C8. When the turret unloading mechanism swings the mount into position the jaws of the chute loading mechthem. Shaft C3 is then rotated counter-clockwise about its axis due to an opposite rotation in shaft C1 which is geared thereto by gears C9 and CI. causing jaw C l to close on the mount. Jaw C2 doesn'ot turn as sleeve C5 on which it is niounied has a protuberance CII which lies against the stop screw in arm CI2 of bracket C5.

A counter-clockwise rotation then occurs in shaft C1 bracket C5 to swing over the storage chute being loaded nnce friction is produced between the bracket and shaft by blocks and springs (not shown) below each of the screws CI3. The

bracket is properly located when it strikes the stop screw in arm CH of the standard C8 whereaooaoao passed through the mount due to a faulty mount,

has a number of teeth equal to the numberof mounts fed onto one chute. The mechanism is B55 in the bracket B56 clamped theretomoves fastened to pin B59, spring B53 cannot pull the bracket C6 which is supported by shaft C1.which anism are open and the mount is placed between upon furtherturning of shaft C1fturnsshaft or.

During the turning of shaft C3 both jaws are swung down to the position shown in Figs. 8 and -9 whereupon protuberanceCIl strikes the stop 7 screwin'arm CI5 of bracket C6 causing the jaws to open. Both jaws move together while turning since friction is provided between sleeve C5 and shaft C3 by the slugs CIG located below springs CI'Fand screws CI8. The mount is securely held by the jaws during the turning as spring CIS which is located between and in apertures of jaw. C2 and sleeve C5 keeps them together. The released mount drops onto the storage chute and the mechanism is'returned to the former position by a clockwise turning of shaft C1. In returning, the bracket C6 is swung until it strikes stop screw in arm CZB (Fig. 1) of standard C8 whereupon the jaws turn into position and are closed after a mount has been placed therebetween. Shaft C1 is operated from cam C2I which is-located on a cam shaft of the mount making machine and which is engaged by roller C22 at the end of arm 'C23 on shaft C24. This shaft operates shaft C1 through gears C25 and C26 and turns in bracket C21 by which it is supported.

The mount dropped from the chute loading mechanism C falls onto the rails of a storage chute D located in juxtaposition with this mech- 'anism. -"As shown in Figs. 1, 10 and 11, there are eight of these chutes each of whichconsists of side rails DI and D2 and guide rail D3. The rails arefastened together at the back end by block D4 and the forward/end of rails DI and D2 are fastened together by yoke D5 as shown in Fig. 11. The guide rail D3 is held in position by screws. D5/ D1, D8 which extend from the bracket'DS attached to said yoke. The chutes are each supported by an arm DI Ii to which they are attached by -means of block DH and pin ,DI2, the arm DII'I being attached in turn to yoke DI3. The arms of the yokes are 'eachslidably mounted on the fixed vertical shaft DI I extending from standard DI5 and are so arranged as tosupport each chute on the same plane as the others without interfering with the free turning of the chute ahead of it in a clockwise direction. The standard DI5 rests on a table 31' only partiallyshown located between machines. A spring DIG is provided between a post in block DH and another post in arm DIIl so that the chutes will normally tilt toward their closed end. In this loading position the inner end of the chute rests against stop screw DH in the arm DH! and the tilt thereof causes the mounts placed thereon to slide downagainst the block Dl.

As shown in Fig. 1,,fo'ur storage chutes areor, when before the loading. mechanism, by the stop slide B13 (Fig. 5) of the counting mechanism previously referred to which engages stud DIS extending from arm DIB. The rotating force .is provided by frictional engagement of stud DIS witli wheel D20 whichturns about the hub D2l of standard DI5 and which provides a circular track in which the head of said stud is located. Friction is produced by two oppositely disposed slugs D22 and D23 in'a transverse-hole in the head of stud' DIS located in the track which are pressed outward against the sides of said track by the wedge D24 located below spring D25 and screw D25 in the shank of said stud. A'portion of the ways is closed off by rings D21 and D28 so the head of the stud may not slip out. Wheel D20 is turned by a chain D29 partially shown in Fig. 15 which engages sprocket D30 of said wheel and which is driven by sprocket D3l on cam shaft 38 indicated by center line D32 in Figs.

and 14. The chain also passes around idler sprockets D33 and D34, the former of which turns about stud D35 in standard D36 and the latter of which turns about stud D31 on arm D38. The 10 chain is tightened by turning arm D38 about post D39 which is supported by standard D40 and then clamping said arm in place by tightening nut D4 l. Guard D42 (Fig. 1) covers the chain drive. -After the desired number of mounts have been counted onto the chute and it has been released as previously described, it swings around 180 to the unloading position.

' In most cases the chute does not enter the unloading position directly but swings against preceding chutes which rest against the particular chute being unloaded. In 'Fig. 1 two chutes are shown behindthe chute being unloaded. The unloading chute is tilted down at its outer end so the mounts will slide therefrom and is held in position by stop slide El which engages stud Dl8. The tilting is produced by finger E2 which engages roller D43 on a pin in block DH pulling the forward end of the chute down so the outer rails DI and D2 thereof straddle vane E3 of -block E4. Finger E2 is pivoted about screw E5 in block E4 by rod E6 which is attached to arm E! (Fig. 14) on shaft E8 and moves down when roller E9" of arm El0 also on said shaft comes over a low part of cam Ell (Fig. 10). Spring Eli which extends between at post in arm El and a fixed fastening causes the roller E9 to follow the cam.-v

The rnounts passing off the storage chute as shown in Figs. 12 and 13, slide onto rails El2 and El3of the stationary chute E and pass down the ways thereof until they strike the jaws of the escapementmechanism F. A guide rail El4 is also provided which is loosely mounted on screw El5 of bracket El6 and on another screw (not shown) extending from bracket El'l. Both brackets are attached to block. E4 which is mounted on standard El8 which is in turn mounted on table 31. Since some means of agitation is required to keep the mounts always slid- ':,u. ing down the chute the guide rail El4 is agitated by lever El9.- The rail fits loosely in a slot in the end of lever El9 which pivots about screw E20 and is vibrated by finger E2l (Fig. 13) mounted thereon passing over the teeth of ratchet E22 55' on cam shaft 38. Screw E20 is supported by arm E23 fastened to bracket El6.

In passing down the stationary chute the mounts pass under both arms of feeler-E24 which is fastened to shaft E25 in bracket El 6 and which 1 L0 is turned at intervals so as to rest on edges of.

the rails or the mounts thereon. This motion is produced by arm E26 (Figs. 12, 13, and 15) which is fastened to shaft E25 and engages cam E21 through roller E28. The purpose of the t5 feeler is to give warning of the small supply of the mounts still left on the stationary chute so that the empty storage chute may be released and a loaded chute allowed to index into the unlOading position. The warning is transmitted 70 when the contact E28 on a'rm E29 on shaft E25 strikes contact E30 on arm E3l and as shown in Fig. -17, results in the operation of solenoid E32. Arm E3l is attached to standard El 8. The circuit in which the contacts are connected con- 75 sists of a battery E33 and the coil E34 of a relay E45 from turning counter-clockwise since it cam Ell to turn as the key E58. on which rolle engages cam E60. The roller is made to follo which closes a circuit of greater voltage througl the solenoid E32 when armature E35 makes con tact with contact E36. The solenoid E32, a shown in Figs. 10 and 14, operates through i armature E31 which turns'lever E38 about 'pi E39 in bracket E40 thereby turning counter clockwise the lever E4l to which it is connecte: by link E42. The action places roller E43 on th other arm of lever E4l against the low part 0 cam E44 (Fig. 15) so that it is moved clockwis when the high part of the cam comes below th roller. The resultant action is that ratchet whee E45 (Fig. 14) is turned one tooth since it is en gaged by pawl E46. The pawl E46 is pivoted o a pin E4! in lever EM and is kept in engagemen with the ratchet by spring E48 extending be tween a post in the. pawl and another post i lever E4l-. Pawl E49 prevents the ratchet whee pivotally attached to arm E50 which is attach to stationary post D39. Spring E60 which i stretched between a post in said pawl and an other post in the arm keeps said pawl agains the ratchet wheel. In this particular instanc operation of the solenoid once does not effec the release of the storage chute but after si" operations thereof, the release is effected. Th purpose of this lag is to give time after the re lease for another chute to come'into position-f0 tilting the chutes and to permit the mounts t slide down under the feeler.

The chute tilting and release mechanism ar placed in operation by the cam blocks E5l 0 wheel E52 which is-attached to the ratchet wheel The blocks engage dog E53 which causes leve E54 to turn counter-clockwise. The motio stretches spring E55 which is located betwee posts in lever E54 and standard Elli and-swing the cam segment E56 away from the roller E5 (Figs. 15 and 16) of cam El l. This action cause E51 is attached is then pushed upward engag ing a depression in collar E59 which is. attache to cam shaft 38. A high part of the cam come under roller E9 causing mechanism previous] described to permit the storage chute to tilt back The release of the chute is brought about'by ca E60 (Figs. 10 and 16) which is fastened to ca 0 Ell and results in the lowering of stop slide El The slide operates in ways in standard El8 an is operated by lever E6l to which it is connecte by link rod E62. Lever E6l is fastened to a shaf E63 which is turned by arm E64 which in tu is operated by a roller E65 carried thereby whic the cam by spring E66 which extends betwee a post in lever E6l and another post in the stand ard E18. Since the highest part of cam E6 moves out from under roller E65 before anothe' chute comes into position it will be stopped b the stop slide and after it has come into posi tion a still lower part of thecam comes below th roller so that the stop slide is raised farthe thereby locking stud Dl8 of the chute.

The'mount escapement mechanism as show in'Figs. 12, 13, 18 and 19 consists of two pairs 0 jaws which at intervals separate and release on of the mounts coming down the stationary chut so that it may slide to the end thereof. Th bead 32 of the first mount passing down th chute enters into an aperture Fl formed by ja F2 and by jaw F3 which are mounted on sore F4: and F5, respectively, extending from brack F6. The bead 32 of the following mounts rest against the pocketed bead until the fingers F and F3 of jaws F9 and Flu, respectively, are drawn together, thereby separating the remaining mounts from the lowermost one and preventing further advancement of said mounts. Following this motion jaws F2 and F3 are opened permitting the mount of the bead which was apertures in the respective jaw and fingers. The

hinged feature of the fingers takes care of the variations in head sizes too large to be held by the aperture or pocket FI. Jaws F2 and F3 are closed by spring FI3 and jaws F3 and FIB are closed by spring FI4 each of which extends between posts in the respective pairs of jaws. The

jaws are opened by cam F15 which is mounted on arm FI6 (Fig. 12) and which is oscillated back and forth between the jaws. Arm FI6 is attached to shaft FI1 which is mounted in bracket F6 and is turned by arm FI8 fastened thereto. Bracket F6 is mounted on block E4. As

m'ostclearly shown in Fig. 15, arm FI8 is oper- 7 F2I is mounted in bracket EI1.

The mount released by the escapement mechanism slides down the rails EI2, EI3 (Fig. 12) to the end where it is caught by the up-turned ends E61 thereof. A gate E68 extending from pins E59 in bracket E11 prevents the mount from passing over the chute ends. The mount transfer mechanism G'then swings into the position shown in Figs. 12 and 13 and grips the leading-in wires of a mount just below the bead. The transfer mechanism consists of a stationary jaw GI mounted on arm G2 and movable jaws G3 and G4 which are pivoted on similar screws G in bracket G6. As the jaws are swung into position the movable jaws are spread apart and are away from the stationary jaw. The spreading is brought about by levers G1 'and G8 and by the wedge end of lever G9 located between said jaws.

The levers G1 and G3 pivot on screw-GI!) of the stationary jaw and engage protuberances extending from the movable jaws. The stud GII extending from lever G9 wedges levers G1 and G8 apart causing spring GIZ stretched between the end thereof to expand. The movable jaws are 4 pulled away from the stationary jaw by lever GI 3 which turns bracket G6 about pin GI4 against the pressure of spring GI5. Levers G9 and GI3 v are pivoted on screws GI 6 and GIG, respectively,

-of lever GI 3 engages the cam and both are kept -in engagement with said cam by spring G2I -stretched between posts in both levers. A counterclockwise motion occurring in the cam first brings the movable jaws together since pin GI1 moves away from pin GI3 and then causes the jaws to grip the mount. Themovable jaws are drawn together by spring G22 which extends betweena post in each jaw.

. The mount transfer mechanism raises the gate "E68 when turning 'into the position shown by bringing wire G23 below one of the support wires thereof. The transferring movement is prefieded by a rising movement which brings the mount above the turned-up ends E61 of the chute. A

clockwise turning now occurs in shaft G24 on which both cam GI6 and arm G2 are mounted, thereby causing the transfer jaws to swing to a position below the jaws of the turret H at position U. In this positionstud G25 of arm G2 lies against stop arm G26 of lever G21 (Figs. 12, 13, and The mechanism then rises until. the mount is between the turret jaws whereupon the mount is gripped by the turret jaws and further rotation of shaft G24 occurs, causing the separate rotation of cam GI8 and the opening and spreading of the jaws as described. The arm G2 moves with shaft G24 since a friction bearing cap G28 is pressed thereagainst by the leaf spring G29 extending between screws G30.

Having transferred the mount to the turret, the

the turret so as to clear the mount as the turret indexes. This operation is caused by turningof shaft G24 and by movement of the stop arm G26.

Lever G21 on which arm G26 is mounted turns about shaft 39 (Fig. 15) since the roller G3I thereof engages cam G32 on cam shaft 40. Spring G33 attached to said lever and a stationary part of the machine causes the roller G3I to follow the contour of the cam. Shafts 39 and 40 are sup ported by bracket 4| extending from cam shaft .38 and 'by bracket 4'2 only partially shown which is; mounted on the table of this portion of the machine. Shaft 46 is driven by gear 43 which meshes with gear 44 oncam shaft 38. The vertical shaft G24 is also mounted in bracket 42 and is rotated by gear G34 which meshes with the gear segment G35 of lever G36. The lever G36 pivots transfer mechanism. is allowed to swing under about a pin G31 in bracket 42 and carries a roller I G38 which engages the ways of cam G39 on cam about pin G42 in the table (not shown) and is toperated through a rollerG43 thereon which engages cam G44 on cam shaft 38. Further movement of the transfer mechanism consists in dropping and turning into the position shown in Fig. 12 in which stud G25 isagainst stop screw G45 of the arm G46 .extending from bracket 42, at which position said mechanism was found at the start of this description.

The mount taken by the turret H is gripped between one of eight pairs of jaws mounted thereon. Each of said pairs of jaws consists of a stationary jaw HI (Fig. 12) fastened to turret H2 and a movable jaw 1-13 comprising a laterally extending portion lying on a laterally extending portion of said stationary jaw, in ways in said turret. When the mount is inserted into the pair of jaws at position U these Jews are open since the high part of cam H5 rides behind roller H6'which is attached to the movable jaw by screw H1. The cam H5 is then turned so a low-part is below a the roller allowing the jaws to be closed by spring H6 which extends between a post H9 in the movable jaw and a post HI 0 in the retaining ring HI I. The retaining ring is fastened to the turret and holds the movable turret jaws in theJg-rooves or ways in the turret. Cam H5 is attached to sleeve HI2 and is operated through said sleeve which is turned about shaft HI3 by arm H14. As shown in Fig. 15, arm H14 is operated by cam HI5 on cam shaft 38 through lever HI6 .which engages said cam through a roller Hi1 mounted thereon and is connected to armfHlLby link HI8. Lever 1 on said shaft is permitted. Lever G40 pivots H16 turns about pin H19 in bracket E11 on which said pin is held by collar H20.

After having gripped a mount, the turret is indexed clockwise so that the jaws carrying the mount are advanced one position, after which repeated indexing occurs at intervals until the mount comes into position V, 180 from the loading position U. The turret H2 is attached to shaft H13 which is turned intermittently by ratchet wheel H21 attached to the lower end thereof. 'The ratchet wheel H21 is engaged by pawl H22 of lever H23 which is operated through engagement of the roller H24 on one end thereof with cam H25 on shaft 38. The pawl H22 op;.

H having indentations therein at each of the respective positions which' are engaged by'the slug H31 below spring H32,in the aperture in turret H2. 3 j

The bulb, into which the mount is dropped from the turret H, initially entered this machine through the tube J1 of the bulb escapement mechanism J shown in Figs.'1, 12, 20, and 21. In this instance, apparatus (not shown) of the type disclosed in Patent 1,536,833 to Fagan et aL,

issued May 5, 1925, is used to feed miniature bulbs in a neck-up position into tube J I. The lower end of the tube enters boss J2 which is supported 'by the bracket J3 extending from bracket 42 and which guides the bulbs down onto the bulb turret K. On entering boss J2 the bulbs come against finger J4 which is disposed in an aperture in boss J2 below the bracket and which extends from lever J5. The lever J5 pivots about screw J 6 in bracket J3 and obstructs the path of travel of the bulbs while the jaws J1 and J8 below are open. The finger J4 is withdrawn when-the jaws are closed since the passage is then closed off by the overlapping jaw ends J9 and J10 which opei'ate in passages in the boss J2. The jaws J1 and J8 are'pivoted on screws J I I and J12, respectively, in bracket J3 and are closed by spring J13 whichis located between the outer ends of posts in said jaws extending through apertures in the bracket. Lever J5 is operated by a finger J 14 hinged thereto which engages the spring post extending from jaw J8 against which it is'held by spring J15. Spring J15 'extends between a post in lever J5 and another post in bracket J3.

Jaws J1 and J8 are provided with gear segments J16 and J11 respectively, and will receive the bulb as they are closed and the finger J4 is withdrawn. The reverse action will first segregate the bulb lying on the jaws, since the bulb adjacent thereto will be held by the finger J4, and thenfwlll permit the said segregated bulb to-fall onto the bulb turret K as the jaw ends J9 and J10 are withdrawn. The-mechanism is operated through arms J18 of jaw J1 which is attached.

by means of link J19 to lever J20 (Fig. 5) which is operated from cam J21 on shaft40. Lever J20 pivots about shaft 39 and is turned by spring J22 extending between said lever and a s tationary part of the'machine so that roller J23 thereon is in engagement with cam J2 I.

Since the bulbs are fed intermittently and are of such light weight, they would often stick if they were not freed by the agitation caused by block J24 on lever J25 striking tube J1. Lever J25 turns about pin H19 in bracket E11 and engages through roller J26, cam J21. Spring J28 which extends between lever J25 and a stationary part of the machine causes the roller to be kept in engagement with the cam.

The bulb released by the escapement mechanism J falls onto a head of the bulb turret K which provides the means for transferring the bulb to an unobstructed position from which the bulb transfer mechanism L may take it. The bulb turret consists, as shown in Figs. 12, 22, and 23, of a body portion K1, which carries heads K2 and K3 and is mounted on the upper end of shaft K4. The shaft K4 is slidably mounted in sleeve K5 in ball bearings K6 and K1 on bracket 42.

The bulb released from the escapement means of lever K13 which strikes the end of the pin and moves it longitudinally bringing the reduced section K14 'in alignment with passage K9. Lever K13 swings about shaft 39 and is actuated by cam K15 through roller K16. Spring K11 which extends between lever K13 and a stationary part of the machine keeps roller K16 against the cam.

After the bulb has been. deposited upon the turret head, the said turret is lowered, turned through 180 and then raised again. This action places the other head in position to receive a bulb and places the bulb carrying head in position for the bulb transfer mechanism to take the bulb. The lowering motion results from movement of lever K18 (Fig. 15) which is moved about pin K19 in a stationary part of the machine (not shown) by rotation of cam K21} on shaft 38. R oller K21 on the lever engagesthe ;cam, and links) K22 and collar K23 provide the connection to shaft K4. The rotary motion of the turret is provided by cam K24 (Fig. 15) through lever K25, gear K25- and gear segment screw K28 therein and, as shown in Fig. 15, is operated by the gear segment K21 in the end of lever K25. The lever K25-engages the cam K24 through roller K29 which is held there against by spring K30 extending between posts in said lever and bracket, 42. The operating procedure at the turret loading position results in the shifting of the valve 'pin K11 (Fig. 23);

cutting off the suction to the exposed head since the pin moves so as to close off the passage thereto. The two positions of the valve pin K11 are designated by the reduced sections K31 and ,K32 thereof which are engaged by the ball K33 behind screw K34 and spring K35 in an aperture in the turret body K1.

The bulb transfer mechanism L carries the bulb and the mount which is placed therein to a head of the butt sealing machine; The transfer mechanism is shown in Figs. 1 and 12 and.con-- ed by screws L3 and L4 on arm L5. The mecha-:

nism swings clockwise from the position shown in Fig. 1 to a position adjacent-the bulb, whereupon the jaws are closed thereabout by the rotation of cam L8. The cam is engaged by roller L! of lever L8 which swings about screw L9 in arm L and operates jaw LI through connecting link LIO. Gear teeth in each jaw mesh with each other so the jaws move together. Spring LII located between posts in lever L8 and arm L5 causes the roller L1 to engage the cam L6. Having gripped the bulb, the transfer mechanism is raised, bringing the bulb neck up around the mount in turret H at position V. The elevation is brought about by vertical movement of shaft LI2, on which arm L5 is mounted, which is operated by leverLI3 (Fig. 15) through engagement with collar Ll4 on the end of said shaft. Lever LI3 turns about a. pin LI5 in a stationary part of the machine (not shown) and is operated by a roller also not shown inthe ways 'LI6 of cam LII on shaft 38. The arm L5 is kept from slipping vertically on shaft LI2 by collar LI8 (Fig. 12) and cam L8 which are fastened to said shaft which is supported by sleeve LI9 in ball bearings .L2I and L22 in bracket 42.

The mount is ieleased from the turret and falls into the bulb with the outwardly extending portionsof the leading-in wires slipped between guides (not shown) attached to the trans-' fer jaws which keep the mount from turning. The transfer mechanism now swings to a position over the head 49 ofthe butt sealing machine and drops down until the bulb rests thereon. The turning results from a' counter-clockwise turning of shaft LI2 which the arm L5 follows because of the friction producing bearing cap L23 whichis located below leaf spring L24 on screws L25. The turning is produced in shaft LI2 by sleeve LI9 which is engaged by pin L28 therein and which is turned by the lever L21 (Fig; 15), through gear segment L28 and gear L29. Lever L21 turns about a pin L38 in a stationary part of the machine (not shown) and connects through link L3I to lever L32 which engages through roller L33 the ways of cam L34 on shaft 38 and which turns about pinL35 in a stationary part of the machine (notshowri). Further rotation of shaft LI2 after the lamp rests in the sealing machine head results in the separate rotation of cam L6, thereby opening the jaws LI and L2 since stud L36 (Fig. 12) is in contact with arm L31 of collar L38. Another arm at .the other position of the transfer mechanism stopsrotation thereof and causes the jaws to close. Collar L38 is clamped to a boss on bracket 42. U

Since the failure of mount to be fed cancels the need for a bulb, automatic mechanism is provided for stopping the feeding thereof. This mechanism consists of means for detecting the bracket 42 and supporting stationary contact arm L43 and movable contact lever L44. movablelever L44 pivots about screw L45 and has an arm L45 extending therefrom which engages cam L41 on post H9 of the movable Jaw of the turret at position V. The cam L41 of each head of the turret is set so that the absence bracket 42:

The'

Fig. 17, is connected in a circuit comprising a battery E33 and coil L48 of relay L49. Closing of the battery circuit causes the armature L58 to'be pulled into contact with contact L51 closing a circuit of higher potential through sole noid L52. The solenoid L52 shown inFig. 24 is mounted on the table of the machine adjacent the path of travel of the bulb transfer mechanism which is indicated. With the solenoid in operation, lever L53 takes the position shown, thereby stopping the transfer mechanism before it reaches the pi k-up position. The lever L53 turns about pin 54 in standardL55 and is connected to the armatureLSB of the solenoid by link L51. The tooth L58 in the end of lever L53 engages a shoulder in stud L38 and prevents the .of this mechanism is produced by spring L59 which extends between pin L60 connecting link L5! and lever L53 and a post (not shown) in Mechanism heretofore described which has been operated from cam shaft 38 operates in proper time relation to the butt sealing machine because said cam shaft 38 (Fig. 15) is driven therefrom by means of the chain .41 which meshes with gear 48 thereon.

The butt sealing machine M is of the type closed in Patent No. 1,742,153, Stiles et al., issued December 31, 1929, hereinbefore referred to, and

holds the bulbs by vacuum onhead 49 and grips the outwardly extending 'ends of the leading-in wires between oppositely disposed pairs of jaws 50 and 5 I A tube 52 held by another pair of jaws 53 and 54 (Figs. 1 and 12) is sealed to the neck of the bulb with portions of leading-in wires enclosed in the joint during its course of operations. The finished product is held by the head in position X. a

The bulb assembly is taken from the sealing machine head at position X by the transfer mech anism N to the conveyor chain 0. The transfer mechanism consists, as shown yin Figs. 25 and 26, of a stationary jaw NI mounted on a slide N2, and a pair of movablejaws N3 and N4 on either side of said stationary jaw which pivot on bolt N5 therein. Slide N2 is'supported in ways in bracket N6 in which it is held by plates N1 and N8 attached thereto, said bracket being horizontally mounted on the vertical tube N9 through an arm not shown. The tube N9 also supports bracket NIII which'is connected to bracket N8 .by shaft NII which turns freely in both parts. When the sealing machine M is indexed 'the movable jaws N3 and N4 are drawn farther away from the stationary jaw NI than shown by the engagement curs when arm N" of hub NI8 on the shaft comes in contact with stud NI9 in the slide cam NI5 and moves it forward, thereby withdrawing roller NI3 from the high part of the cam. In

theforward position, the screw in-stud N28 is against stud N2I. The hub Nl8 is driven by gear N22 which is'attached thereto and is {driven by the rack N23 in mesh therewith. The rack rides 7s roller NI3.

in ways in bracket NIO and is held in engagement with the gear by roller N24 on bolt N25 in the bracket. The rack is operated through rod N26 (Fig. -1) from mechanism which is not shown.

After the exhaust tube is gripped, a clockwise rotation occurs in shaft NII which results in a reciprocating motion of .slide N2, thereby transferring the tube to a 'pair of clips OI and 02 on the conveyor 0. Shaft NII moves the slide N2 through gear N21 which is in mesh with the rack N28 cut in the slide. Gear N21 is driven by means of a friction producing bearing cap N29 below leaf spring N30. The movement is terminated when stopscrew N3I on slide N2 strikes bracket N6. The continued rotation of shaft NH opens the jaws NI and N3, N4 by bringing arm N32 against stud NI9, thereby shifting the slide cam NI 5 and bringing the high part of said cam below The conveyor carries the bulb assembly away, whereupon a counter-clockwise rotation occurs in the shaft NI I, which moves slide N2 toward the sealing machine M and, after a bulb assembly is located therein, closes the jaws. In this position of the slide, screw N33 on the end thereof is against the bracket N6.

The conveyor 0 consists of a chain 03 (Fig. 27) which carries a number of pairs of spring clips OI and 02.and rests 04 disposed below said clips on brackets 05. The chain rides on sprockets O6 and 01 which cause the chain to 'be indexed one position at a time at intervals.

The bulb assembly placed in the conveyor by the transfer mechanism finally indexes into position Y from which it is taken by the transfer mechanism P and placed in the exhaust machine Q.

The said transfer mechanism P, shown in Fig. 28, consists of a stationary jaw PI mounted on .arm P2 and a movable jaw P3 pivotally mounted on screw P4 in the stationary jaw. Arm P2 is mounted on rod P which it frictionally engages. At the .positions Y, Z of the mechanism, one or the other of the stop screws P6, P1 is against the stationary post P8. The movable jaw P3 is operated by cam P9 on the end of rod P5 which engages roller PIII on lever PII and turns said lever about pin PI2 in' arm P2. Link P I 3 connects lever PII and the movable jaw P3, and spring P, which is extended between posts in lever PI I and arm P2, keeps roller PIli against cam P9. The parts of the exhaust machine Q face downward so the transfer mechanism after swinging under' 1. A unitary and completely automatic machine for making incandescent lamps comprismounts comprising two lead wires having juxtaposed portfohs which are, held together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to the said juxtaposed portions, transfer mechanism adjacent said mount making machine for transferring a mount directlyfrom saidmount making machine and disposing it. in a glass bulb which is disposed in a neck-up position, a machine for butt-sealing a glass exhaust tube to the neck:of

7 said bulb and enclosing portions of the lead wires ing a mount making machine for manufacturing.

in the joint, amachine for exhausting said bulb I and tipping off said exhaust tube, mechanism for transferring said bulbs having'the mounts sealed therein from said butt sealing machine to said exhausting machine, and means forcausing said mechanisms to operate in proper time relation. 2. A unitary and completely automatic machine for making incandespent lamps comprising a mount making machine for manufacturing mounts comprising two lead wires having juxtaposed portions which are held together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to the said juxtaposed portions, a storage chute, mechanism for transferring said mounts from said mount making machine to said storage chute, a sealing machine for sealing said mounts in glass bulbs, mechanism for transferring said mounts one at a time from said storage chute to said sealing machine, and means for causing said mechanisms to operate in proper'time relation.

' 3. A unitary and completely. automatic machine for making incandescent lamps comprising a mount making machine for manufacturing mounts comprising two lead wires having juxtaposed portions which are held together and support a'filament at their inner ends, the outer ends of said lead wires extending transversely to the said juxtaposed portions, a plurality of storage chutes, mechanism for transferring said mounts from said mount making machine to said storage chutes, a sealing machine for sealing said mounts in a glass bulb, mechanism for transferring said chutes to an unloading position, mechanism adjacent said unloading position for transferring said mounts one at a time from said storage chutes to said sealing machine, and means for causing said mechanism to operate in proper time relation.

4. A unitary and completely automatic machine -for making incandescent lamps comprising a mount making machine for manufacturing mounts comprising two lead wires having juxtaposed portions which are held together by a glass bead and support a filament at their inner ends, the outer ends of said lead wires extending transversely to the said juxtaposed portions, a storage chute, mechanism for transferring said mounts from said mount making machine to said storage chute, mechanism for transferring said chute to an unloading position, mount escapement mechanism located at said unloading position adjacent the end of said chute and engaging with the glass bead portions of said mounts for separating a mount at the end of said chute from the remaining mounts, a sealing machine for sealing said mounts in glass bulbs, mechanism for transferring said mounts one at a time from said storage chute to; said sealing machine, and means for causing said mechanisms to operate in proper time relation. F

5. In a machine of the class described, a transfer mechanism for mounts comprising two lead wires having juxtaposed portions which are .qheld together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to said juxtaposed portions, said transfer mechanism comprising a chute having a pair of parallel rails and a third guide rail parallel to'said pair of rails and located midway therebetween, mechanism located at a loading position of said chute for disposing a plurality of mounts thereon in an inverted position with the transverse outer ends of thelead wires on said time from said unloading position, and means for causing said mechanisms time relation.

6. In a machine of the class described, a transfer mechanism for mounts comprising two lead wires having juxtaposed portions which are to operate in proper .held together and support a filament at their inner ends, the outer ends of said lead wiresex: tending transversely to said juxtaposed portions, said transfer mechanism comprising a plurality of radially disposed chutes each having a pair of parallel rails, said chutes being pivotally mounted on avertical shaft, mechanism ,for rotating said chutes successively into a loading position and an unloading position, mechanism located at said-loading position for disposing a plurality of mounts one at a time on 'a chute with the transverse outer ends thereof riding on the said rails of said chute, mechanism at said unloading position for removing said mounts one at a time from said chute, and means for causing said mecha nisms to operate in proper time relation.

'7. In a machine of the class described, a transfer mechanism for mounts comprising two lead wires having juxtaposed portions which are held together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to said juxtaposed portions, said transfer mechanism comprising a plurality of radially disposed chutes each having a pair .of

parallel rails, said chutes being pivotally mounted on a vertical shaft, mechanism for rotating said chutes successively into a loading position and an unloading position, mechanism for tilting the outer ends of said chutes up at the loading positionand down at the unloadingposition, mechanism located at said loading position for disposing a plurality of mounts on a chute with the transverse outer ends thereof riding on the said rails of said chute, mechanism at said unloading position for removing said mounts one at a. time from said chutes, and means for causing said mechanisms to operate in proper time relation.

" 8. In a machine of the class described for transferring mounts comprising two lead wires having juxtaposedportions' which are held together and support a filament at their inner ends,

the outer ends of said lead wires extending transversely to said juxtaposed portions, a storage chute having a plurality of mounts disposed therein, mechanism for transferring said chute to an unloading position, mount escapement mechanism located at said unloading position adjacent the end of'said chute for separating a mount at the end of said chute from the remaining mounts, a horizontally disposed mount turret having a plurality of jaws at the periphery thereof, a pair of transfer jaws, mechanism for causing said transfer jaws to grip a separated mount at the end of said storage chute and deliver it to a pair of jaws on said turret, a'bulb turret comprising a bulbs disposed therein in mechanism for rotating said mount turret to cause a pair of jaws thereon to register with a bulb on said bulb turret and to cause said jaws to be opened to, deposit the mount gripped thereby in said bulb, a pair of transfer jaws, mechaa neck-up position,

wires having juxtaposed portions which are held together by a glass bead and support a filament ends of said lead at their inner ends, the outer wires extending transversely to the said juxtaposedportions, a storage chute, a 7

pair of vertically disposed jaws mounted on the end of a horizontally disposed arm for transferring s'aid mounts from a mount making machine to said storage chute, mechanism for causing said jaws to grip a mount on said mount making machine and then swing toward said chute and turn in a vertical plane throughfsubstantially 180 degrees to deposit said mount on said chute in an inverted position, mechanism for transferring said chute to an unloading position, mount escapement mechanism located at said unloading position adjacent the end of said chute and engaging with the glass bead portions of said mounts for separating a mount at the end of said chute from the remaining mounts, mechanism for'transferring said mounts one at a time from said storage chute to a sealing machine, and means for causing said mechanisms to operate in. proper time relation.

10. In a machine of the class described, a transfer mechanism for mounts comprising two lead wires having juxtaposed portions which are tending transversely to said juxtaposed portions,

said transfer mechanism comprising a plurality of radially disposed chutes each having a pair of parallel rails, said chutes being pivotally mounted on a vertical shaft, mechanism for rotating said chutes successively into a loading position and an unloading position, mechanism located at said loading position for disposing a plurality of mounts one at a the transverse outer ends thereof riding on said rails of said chute, mechanism for recording the number of mounts deposited on a chute at said loading position and for indexing said chute when the proper number of mounts have been deposited thereon, mechanism at said unloading position for removing said mounts one at a time from said chute, and means for causing said mechanisms to operate in proper time relation.

11. In a machine of the class described, a transfer mechanism for mounts comprising two lead wires having juxtaposed portions which are held together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to said juxtaposed portions. said transfer mechanism comprising a plurality of radially disposed chutes each having a pair of ed on a vertical shaft, mechanism for rotating time on a chute with v said chutes successively into a loading position and an unloading position, mechanism located at said loading position for disposing a plurality vof mounts one at a time on a chute with the transverse outer ends thereof riding on said rails of said chute, mechanism for recording the number of mounts deposited on a chute at said unload ing position comprising a ratchet wheel having a plurality of notches in the periphery thereof corresponding to the number of mounts to be deposited on the chute, a pawl engaging said .notches, mechanism for actuating said pawl to rotate said ratchet wheel the distance between successive notches each time a mount is deposited on the said chute, and cam mechanism for causing said chute to be indexed away from said loading position upon completion of a revolution of said'ratchet wheel, mechanism at said unloading position for removing said mounts one at a time from said chute, and means for causing said mechanisms to operate in proper time relation.

12. In a-device of the class described, the combinatlon of a storage means, mount feeding mechcausing the anism for depositing mounts one at a time in said storage means and mechanism for recording the number of mounts deposited, in said storage means comprising a ratchet wheel having a plurality of notches in the periphery thereof corresponding to the number of mounts to be deposited in said storage means. a pawl engaging said notches, mechanism for actuating said pawl to rotate said-ratchet wheel the distance between successive notches each time a mount is deposited in said storage means, and cam'mechanism' for feeding to said storage means to be interrupted-upon completion of a revolution of said ratchet wheel.

13. In a device of the class described, the combination of a storage means, mount feeding mechanism for depositing mounts one at a time in said storage means and mechanism for recording the number of mounts deposited in said storage means comprising a ratchet wheel having-a plurality of notches in the periphery thereof corresponding to the number of mounts to be deposited in said storage means, a pawl engaging said notches, mechanism ior actuating said pawl'to rotate said ratchet wheel the distance between successive notches each time a mount is deposited in said storage means, testing means comprising an electrical circuit including said mount and a relay whereby when said mount is defective and no current passes therethrough thesaid mount feeding mechanism is rendered inoperative and the said pawl is displaced from said ratchet wheel to prevent rotation thereof, and cam mechanism for causing the feeding to said storage means to be interrupted upon completion of a revolution of said ratchet wheel.

1a. In a machine of the class described, a

transfer mechanismfor mounts comprising two lead wires having juxtaposed portions which are held together and support a filament at their inner ends, the outer ends of said lead wire extending transversely to said juxtaposed portions, said transfer mechanism comprising a plurality oi radially disposed chutes each having a pair of parallel rails, said chutes being pivotally mounted'on a verticalshaft, mechanism for rotating said chutes successively into a loading-Desi aoos oso tion and an unloading position, transfer mechanism located at said loading position for dispos mg a plurality of mounts one at a time on a chute with the transverse outer ends thereof riding on said rails of said chute, a. stationary chute at said unloading position with which said radially -disposed chutes register successively to form acontinuation thereof, a Ieeier disposed adjacent said stationary chute and engaged by the mounts as they slide down, mechanism actuated by said feeler for indezdng a radially disposed chute away from said unloading position .when the last mount on said chute has passed under said feeler, mechanism at said unloading position for removing said mounts one at a time from said chute, and means for causing said mechanism to operate in proper time relation. n

15, A unitary' and completely automatic machine for making incandescent lamps comprising a mount making machine for manufacturing mounts comprising two lead wires having juxtaposed portions which are held together and support a filament at their inner ends, the outer ends of said lead wires extending transversely to the said juxtaposed portions, a bulb turret comprising a plurality of heads, mechanism for feeding bulbs to the heads of said turrets one at a time in a neck-up position, mount transfer mechanism for transferring the mounts from said mount making machine and depositing them in the bulbs in said turret heads, a sealing machine for sealing glass tubes to the necks of said bulbs and enclosing portions of the lead wires of the mount in the joint, transfer mechanism for transferring bulbs having mounts disposed therein from said turret heads to said sealing machine; and means for causing said mechanisms to operate in proper time relation. -16. In a device of the class described, a bulb turret comprising a plurality of heads,,mechanism for feeding bulbs to the heads of said turret one at a time in a neck-up position, mount feeding neck, mechanism for transferring the bulbs having the mounts disposed thereinfrom said bulb turret heads to a sealing machine, and means for causing said mechanisms to'operate in proper time relation. JOHN F. DONOVAN.

. GEORGE ILILINQWQRTH. 

